Deformation Driven Programmable Metamaterials and Soft Machines

Tang, Yichao

January 2018

Mechanical metamaterials are becoming an emerging frontier in scientific research and engineering innovation due to its unique properties, arising from innovative geometrical designs rather than constituent materials. Reconfigurable metamaterials can change their shapes and structures dramatically under external forces or environmental stimuli. It offers an enhanced flexibility in performance by coupling dynamically changing structural configuration and tunable properties, which has found broad potential applications in 3D meso-structures assembly and programmable machines. Despite extensive studies on harnessing origami, the ancient paper folding art, for design of mechanical metamaterials, the study on utilizing its close cousin, kirigami (“kiri” means cut), for programmable reconfigurable mechanical metamaterials and machines remains largely unexplored. In this dissertation, I explore harnessing the uniqueness of cuts in kirigami for achieving extraordinary mechanical properties and multifunctionalities in krigami-based metamaterials, as well as its potential applications in programmable machines and soft robotics. I first exploit the design of hierarchical cuts for achieving high strength, high stretchability, and tunable mechanical properties in hierarchical rotation-based kirigami mechanical metamaterials. Hierarchical line cuts are introduced to a thin sheet composed of non-stretchable materials (copy paper), less stretchable materials (acrylics), and highly stretchable materials (silicone rubber, PDMS), to explore the role of constituent material properties. The cut unit in the shape of solid rectangles with the square shape as a special case was demonstrated for achieving the extreme stretchability via rigid rotation of cut units. It shows that a higher hierarchical level contributes to a higher expandability and lower stiffness to constituent material. However, when such kirigami structure is applied onto less-stretchable materials (e.g. acrylics), its stretchability is almost eliminated regardless of the hierarchical level, because severe stress concentration at rotation hinges leads to the structure failure at the very beginning stage of pattern transformation. To address this challenge, I propose a hinge design which can significantly reduce the stress concentration at cut tips and enable high stretchability for rotation-based kirigmai structure, even on acrylic thin sheet. I also study the tunable photonic behavior of proposed hierarchical kirigami metamaterial by simple strain-induced structural reconfiguration. I then explore the programmability of kiri-kirgami structures by introducing notches to the simplest kirigami structure patterned with parallel line cuts for breaking its deformation symmetry. Engraving the flat-cut kirigami structure enables programmable control of its out-of-plane tilting orientation, thus generating a variety of inhomogeneous structural configurations on demand. I find that compared to the its counterpart without engraving notches, the introduced notches have a negligible effect on both the stress-strain curve over the large strain range and the extreme stretchability, however, they reduce the critical buckling force largely. Furthermore, I demonstrate the adaptive kiri-kirigami structure through local actuation with its tilting directions to be programmed and switched in response to the change of environmental temperature. Lastly, I demonstrate the potential promising outcome of kiri-kirigami structures as adaptive building envelope in energy efficient buildings, especially in electric saving for lighting and cooling load saving through numerical simulation. In addition to kirigami based soft metamaterials, I also investigate the utilization of soft materials and soft structures for robotics functions. First, I explore the design of soft doming actuator upon pneumatic actuation and its implications in design of multifunctional soft machines. I propose a novel bilayer actuator, which is composed of patterned embedded pneumatic channel on top for radial expansion and a solid elastomeric layer on bottom for strain-limiting. I show that both the cavity volume and bending angle at the rim of the actuated dome can be controlled by tuning the height gradient of the pneumatic channel along the radial direction. I demonstrate its potential multifunctional applications in swimming, adhesion, and gripping. I further explore harnessing doming-based bilayer doming actuator for developing soft climbing robot. I characterize and optimize the maximum shear adhesion force of the proposed soft adhesion actuator for strong and rapid reversible adhesion on multiple types of smooth and semi-smooth surfaces. Based on the switchable adhesion actuator, I design and fabricate a novel load-carrying amphibious climbing soft robot (ACSR) by combining with a soft bending actuator. I demonstrate that it can operate on a wide range of foreign horizontal and vertical surfaces, including dry, wet, slippery, smooth, and semi-smooth ones on ground, as well as under water with certain load-carrying capability. I show that the vertical climbing speed can reach about 286 mm/min (1.6 body length/min) while carrying over 200g object (over 5 times the weight of ACSR itself) during climbing on ground and under water. / Mechanical Engineering

Engineering, Mechanical

Mechanics

Robotics

Doming Actuator

Kirigami

Mechanical Metamaterials

Programmable Machines

Reconfigurable Soft Structures

Soft Robotics

Towards an Understanding of Zebrafish Epiboly: The Characterization of the Epiboly Initiation Mutant Eomesodermin A

Du, Susan

31 December 2010

How cell movements are coordinated during morphogenesis is not well understood. We focus on epiboly, which describes the thinning and spreading of a multilayered cell sheet. The first phase of epiboly involves the doming of the yolk cell up into the overlying blastoderm. We previously showed that over-expression of a dominant– negative eomesodermin a construct inhibits doming. Here I report my analysis of embryos lacking both maternal and zygotic Eomesodermin A (MZeomesa). eomesafh105 mutant embryos (1) exhibit a doming delay, (2) have defective yolk cell microtubules, (3) have tightly packed deep cells with more bleb – like protrusions and (4) express early endoderm markers abnormally. Despite these phenotypes, the majority of MZeomesa embryos are able to complete epiboly and form endodermal derivatives. In both Xenopus and mice, Eomesodermin has also been implicated in the regulation of gastrulation movements and cell fate specification, suggesting a conserved role for Eomesodermin throughout vertebrate development.

Zebrafish

Epiboly

Morphogenesis

Gastrulation

Eomesodermin A

T-box transcription factor

Endoderm

Microtubules

yolk cell

doming

0379

0307

0472

Towards an Understanding of Zebrafish Epiboly: The Characterization of the Epiboly Initiation Mutant Eomesodermin A

Du, Susan

31 December 2010

How cell movements are coordinated during morphogenesis is not well understood. We focus on epiboly, which describes the thinning and spreading of a multilayered cell sheet. The first phase of epiboly involves the doming of the yolk cell up into the overlying blastoderm. We previously showed that over-expression of a dominant– negative eomesodermin a construct inhibits doming. Here I report my analysis of embryos lacking both maternal and zygotic Eomesodermin A (MZeomesa). eomesafh105 mutant embryos (1) exhibit a doming delay, (2) have defective yolk cell microtubules, (3) have tightly packed deep cells with more bleb – like protrusions and (4) express early endoderm markers abnormally. Despite these phenotypes, the majority of MZeomesa embryos are able to complete epiboly and form endodermal derivatives. In both Xenopus and mice, Eomesodermin has also been implicated in the regulation of gastrulation movements and cell fate specification, suggesting a conserved role for Eomesodermin throughout vertebrate development.

Zebrafish

Epiboly

Morphogenesis

Gastrulation

Eomesodermin A

T-box transcription factor

Endoderm

Microtubules

yolk cell

doming

0379

0307

0472

DYNAMIQUE DU RIFTING CONTINENTAL DE 30 Ma A L'ACTUEL DANS LA PARTIE SUD EST DU TRIANGLE AFAR. TECTONIQUE ET MAGMATISME DU RIFT DE TADJOURA ET DES DOMAINES DANAKIL ET D'ALI SABIEH, REPUBLIQUE DE DJIBOUTI.

Ahmed Daoud, Mohamed

19 June 2008

Les résultats acquis au cours de ce travail à propos (i) des basaltes récents du Golfe de Tadjoura et (ii) les séries synrift initiales des domaines Ali Sabieh et Danakil apportent de nouvelles contraintes sur, repectivement, la cinématique récente du Rift Tadjoura et celle, plus ancienne, des zones marginales de la dépression Afar. Mais, ils apportent aussi des éléments permettant de discuter, à une échelle plus vaste, certains aspects de la dynamique du rift Afar, sensu lato.<br />- L'étude structurale des basaltes récents (2.8-1.1 Ma) des marges du Golfe de Tadjoura nous conduit à interpréter la structure générale du rift Tadjoura en termes d'hémi-graben, à vergence sud, développé au-dessus de traps antérieurs, et accommodant une extension estimée à 25-30%. L'âge décroissant des structures vers la partie axiale, immergée, du dispositif reflète la concentration progressive des déformations au cours du temps. L'analyse géométrique et statistique des populations de failles exposées le long des deux flancs de l'hémi-graben met en évidence, au niveau du système extensif méridional, un gradient croissant de déformation vers l'W, en direction de la zone transverse d'Arta. Ce dispositif est attribué au blocage frontal de la propagation des structures axiales du Golfe contre une discontinuité mécanique pré-existante. Dans le modèle cinématique proposé, le transfert de l'extension depuis le rift Tadjoura vers la zone du Ghoubbet s'effectue, non pas par l'intermédiaire de structures en échelon, mais par un saut de rift (en sénestre) de part et d'autre de cette discontinuité sub-méridienne à polarité ‘Mer Rouge'.<br />- L'étude structurale et géochimique/géochronologique des séries volcaniques d'Ali Sabieh et de leur substratum mésozoïque démontre les faits suivants :<br /> . Les ensembles volcaniques initiaux se mettent en place entre 26-19 Ma (complexe intrusif-effusif d'Ali Sabieh), cad. environ 6 Ma après les traps éthiopiens et yemenites qui n'ont donc pas d'équivalents dans ce secteur intermédiaire. <br /> . La partie intrusive du complexe magmatique est interprétée en termes de laccolithe dont la mise en place provoque la structuration antiformale de la couverture mésozoïque, puis son démantelement partiel, sous forme d'enclaves, lors d'un processus de ‘block stoping'.<br /> . L'antiforme d'Ali Sabieh implique jusqu'aux séries acides Mablas (15-11 Ma) et il est scéllé, sur ses flancs, par les basaltes Somali (7.2-3.0 Ma) et du Dalha (8.6-3.8 Ma). <br />- Un tout autre mécanisme est proposé pour l'édification des reliefs Danakil qui résultent de mouvements verticaux beaucoup plus jeunes, postérieurs (ou synchrones) des Basaltes Stratoïdes, et d'origine probablement tectonique, en liaison avec le rifting Tadjoura et/ou Asal.<br />- Ces résultats ont aussi des implications sur la dynamique de l'ensemble du dispositif Afar, et de nouvelles hypothèses sont proposées au sujet (i) du sens de propagation des axes de rift récents-actifs recoupant la dépression Afar et de leur appartenance aux systèmes Golfe d'Aden ou Mer Rouge, (ii) de la distribution spatiale du magmatisme initial (à 30 Ma), de type trap, au niveau de deux sous-provinces, séparées par un domaine amagmatique, et (iii) de l'évolution du domaine Danakil et de la nature de sa limite orientale avec la Mer Rouge, considérée comme une discontinuité héritée de premier ordre, de part et d'autre de laquelle les mécanismes de l'extension sont dominés par des processus, soit magmatiques (W), soit tectoniques (E).

Afar

Rift de Tadjoura

Failles

Propagation de rift

Extension

Danakil

Ali Sabieh

Laccolite

Doming

Manteau appauvri

Plume

Elements majeurs et en traces